Yan Xuefeng, Noergaard Martin, Morse Cheryl L, Liow Jeih-San, Hong Jinsoo, Greve Douglas, Telu Sanjay, Kim Min-Jeong, Montero Santamaria Jose A, Galassi Anthony, Feng Ningping, Williams Avram Sarah K, Usdin Ted B, Wu Shawn, Zhang Andrea, Manly Lester S, Jenkins Madeline, Van Buskirk Maia, Lee Adrian, Zoghbi Sami S, Pike Victor W, Zanotti-Fregonara Paolo, Innis Robert B
Intramural Research Program, National Institute of Mental Health, Bethesda, Maryland.
Department of Computer Science, University of Copenhagen, Copenhagen, Denmark; and.
J Nucl Med. 2025 Mar 3;66(3):398-404. doi: 10.2967/jnumed.124.268525.
Cyclooxygenase-2 (COX-2) is present in a healthy brain at low densities but can be markedly upregulated by excitatory input and by inflammogens. This study evaluated the sensitivity of the PET radioligand [C]-6-methoxy-2-(4-(methylsulfonyl)phenyl)--(thiophen-2-ylmethyl)pyrimidin-4-amine ([C]MC1) to detect COX-2 density in a healthy human brain. The specificity of [C]MC1 was confirmed using lipopolysaccharide-injected rats and transgenic mice expressing the human gene, with 120-min baseline and blocked scans using COX-1 and COX-2 selective agents. Twenty-seven healthy participants were injected with [C]MC1. Ten of these participants received 2 PET scans: a baseline study followed by blockade with celecoxib (600 mg orally), a preferential COX-2 inhibitor. Seventeen participants underwent test-retest imaging. All scans included concurrent arterial sampling. The tissue-to-plasma ratio at equilibrium (i.e., total distribution volume) was determined using a 2-tissue compartment model (2TCM). In humanized transgenic COX-2 mice, 70%-90% of [C]MC1 brain uptake was blocked by nonradioactive MC1 and celecoxib (a COX-2 selective inhibitor) but not by PS13 (a COX-1 selective inhibitor), thereby confirming specific binding to human COX-2. Radioactivity in the human brain peaked at a concentration of about 4.0 SUV, indicating good passage through the blood-brain barrier. Values for the total distribution volume achieved stability after 80 min, indicating no radiometabolite contamination. Celecoxib reduced radioligand binding in neocortical areas by 25% but had little or no effect in subcortical regions and the cerebellum, which correlated with COX-2 messenger RNA expression levels. Binding site occupancy by celecoxib was virtually complete, as determined by the Lassen plots. Test-retest reliability was moderate (intraclass correlation coefficient, 0.65) but had relatively large variability (absolute retest variability, 20%). Reference tissue methods yielded results comparable to those of 2TCM but reduced retest variability by up to 75% and reduced intersubject variability (coefficient of variation) by about half. Thus, compared with 2TCM, which requires arterial blood, the reference tissue method is expected to significantly reduce the sample sizes required to detect statistically significant differences between groups. [C]MC1 has adequate sensitivity to measure the low density of COX-2 in a healthy human brain, suggesting it can also quantify the COX-2 elevations expected in human disorders associated with neuroinflammation.
环氧化酶-2(COX-2)在健康大脑中以低密度存在,但可被兴奋性输入和炎症原显著上调。本研究评估了正电子发射断层扫描(PET)放射性配体[C]-6-甲氧基-2-(4-(甲基磺酰基)phenyl)-4-(噻吩-2-基甲基)嘧啶-4-胺([C]MC1)检测健康人脑中COX-2密度的敏感性。使用注射脂多糖的大鼠和表达人COX-2基因的转基因小鼠,通过120分钟的基线扫描以及使用COX-1和COX-2选择性药物进行阻断扫描,证实了[C]MC1的特异性。27名健康参与者注射了[C]MC1。其中10名参与者接受了2次PET扫描:一次基线研究,随后用塞来昔布(口服600毫克)进行阻断,塞来昔布是一种选择性COX-2抑制剂。17名参与者进行了重测成像。所有扫描均包括同步动脉采样。使用双组织室模型(2TCM)确定平衡时的组织与血浆比值(即总分布容积)。在人源化转基因COX-2小鼠中,70%-90%的[C]MC1脑摄取被非放射性MC1和塞来昔布(一种COX-2选择性抑制剂)阻断,但未被PS13(一种COX-1选择性抑制剂)阻断,从而证实了与人类COX-2的特异性结合。人脑中的放射性在浓度约为4.0标准摄取值(SUV)时达到峰值,表明其能很好地通过血脑屏障。80分钟后总分布容积值达到稳定,表明没有放射性代谢物污染。塞来昔布使新皮质区域的放射性配体结合减少了25%,但对皮质下区域和小脑几乎没有影响,这与COX-2信使核糖核酸表达水平相关。根据拉森图确定,塞来昔布的结合位点占有率几乎达到完全阻断。重测可靠性中等(组内相关系数为0.65),但变异性相对较大(绝对重测变异性为20%)。参考组织方法得出的结果与2TCM相当,但将重测变异性降低了多达75%,并将受试者间变异性(变异系数)降低了约一半。因此,与需要动脉血的2TCM相比,参考组织方法有望显著减少检测组间统计学显著差异所需的样本量。[C]MC1具有足够的敏感性来测量健康人脑中低密度的COX-2,这表明它也可以量化在与神经炎症相关的人类疾病中预期的COX-2升高。
